If this is not your first visit to the SuppVersity, I am confident you've read about the ergogenic effects of sodium bicarbonate aka baking soda before. If you haven't here is the short version: Sodium bicarbonate will act as a systemic acid buffer during workouts. That's in contrast to beta-alanine which works exclusively in the muscle, but has very similar, in some studies albeit significantly more pronounced and first and foremost acute beneficial effects on exercise performance.

No loading, no waiting, no hoping. You simply wash down 20g of bicarbonate (better 0.3g/kg body weight) before the race of your life and - as long as your tummy can stomach it - see / feel the benefits during the race.

You can learn more about bicarbonate and pH-buffers at the SuppVersity

The Hazards of Acidosis

Build Bigger Legs W/ Bicarbonate

HIIT it Hard W/ NaCHO3

Creatine + BA = Perfect Match

Bicarb Buffers Creatine

Beta Alanine Fails to HIIT Back

In his thesis paper, Michael E. Percival investigated the effects of bicarbonate supplementation on the cellular adaptation process in response to high intensity interval training (HIIT).

"Acute and chronic high-intensity interval exercise is a potent stimulus to influence a
number of physiological adaptations with implications for health and athletic performance. [...] Due to the intense nature of
this training modality and associated disturbance to muscle pH, which has been implicated in
fatigue, it has been hypothesized that augmenting the body’s natural buffering capacity through
nutritional means may be a strategy to augment training adaptations. One way of doing this
is through the ingestion of NaHCO
3
prior to exercise, which has shown to have ergogenic effects
allowing athletes to perform more work with each training session. In addition, greater
mitochondrial and performance adaptations are seen when HIIT is preceded by NaHCO3
ingestion even when work is matched (Edge. 2006; Thomas. 2007; Bishop. 2010)."

Percival's goal was now to finally establish what exactly it is that gives bicarbonate the adaptational edge, so to say. To this ends, Michael E. Percival had his subjects, nine active men (22 ± 2 y; 78 ± 13 kg, VO²peak = 48 ± 8 mL/kg/min; mean ± SD) perform the same 10 x 60 s HIIT cycling protocol on two occasions, either with

0.2 g/kg body weight sodium bicarbonate (BICARB) or

an equimolar dose of a placebo, sodium chloride (PLAC),

both ingested in two equally sized doses that were ingested 30 minutes after the breakfast - a means to minimize gastrointestinal distress | and in the study at hand it worked: There was not difference in gastrointestinal complaints between placebo and bicarbonate trial.

The two trials were separated by 1 week, the subjects had to perform their 10 all out cycling bouts at an intensity of ~263 ± 40 W - more than enough to bring all of them up to the 90%+ heart rate zone. , interspersed by 60 s of recovery. Total work during each trial was identical for a given subject.

A brief reminder of the benefits of bicarbonate: Regulation of hydrogen ions (H
+
) or pH within homeostatic concentrations is critical for
proper physiological function. The factors contributing to the change in muscle pH seen during intense
exercise are numerous and the role of each factor remains hotly debated. However, classically it is believed that a large contributor of H
+
is through the
accumulation of lactate produced from glycolysis. Next to internal buffers, which are exhausted relatively quickly, the shuttling
of H
+
and lactate across the sarcolemma is also believed to play an important role in the
maintenance of pH during intense exercise. This is due to the extracellular buffering capacity HCO3
-
which is
believed to promote the efflux of H
+
from active muscles ( Hollidge-Horvat. 2000; Bishop. 2004).

One way to facilitate this process is obviously the provision of exogenous bicarbonate in form of NaHCO3. According to the most recent meta-analysis by Carr et al. (2011), even acute dosing will lead to performance enhancements of 1.7% during short high intensity activities as sprinting. As Percival points out, it does eventually not matter how "sodium bicarbonate imposes its ergogenic effects, the ability to allow athletes to work harder may enhance the exercise stimulus", anyways, and thus contribute to faster / greater size and strength gains. There is yet also accumulating evidence "that NaHCO3 supplementation can improve adaptations independent of greater work output." One of the underlying factors, i.e. the increase in the mitochondrial builder protein PGC-1a has been identified in the study at hand.

Figure 2: Bicarbonate increases mitochondrial respiration specifically during longer-duration exercise (Bishop. 2010) - the study at hand does not just confirm the results of the previous rodent study, it does also provide information about the underlying mechanism that's responsible for the accelerated mitochondrial adaptation w/ sodium bicarbonate.

The latter is important, because otherwise the significant differences in PGC1-a expression (see Figure 1), of which the study at hand indicates that they are the most probably reason for the previously cited significant adapational benefits from bicarbonate supplementation (compare Figure 2), could be a mere function of the training volume.

Based on the data from blood draws and needle biopsies
from the vastus lateralis we can now conclude that it is the increase in PGC-1α mRNA, which was increased after 3 h of recovery to a greater extent in
BICARB vs. PLAC (~7- vs. 5-fold, p < 0.05) that is responsible for the enhanced adaptations after chronic supplementation.

Speaking of which, as I've previously pointed out, I truly believe that the serial loading protocol, as described by Driller et al. (2012) is the most promising dosing scheme for the long(er)-term use of sodium bicarbonate supplements (read my write-up for more information). Issues with increasing blood pressure or calcium loss as they have been reported for very high sodium chloride intakes in susceptible individuals should, as I repeatedly pointed out, not be an issue (Luft. 1990). In pre- and post-menopausal women on high-protein diets, the addition of small amounts of sodium bicarbonate is in fact an effective way to increase calcium retention and thus any potential negative effects on bone health that may arise as a consequence of protein-induced hypercalciuria (Lutz. 1984).

The increase of PGC1-a is significant, because the signaling protein has previously been shown to exert "IGF-1 Promoting, Myostatin Reducing, Muscle Building Effects" | learn more

Bottom line: While I am pretty sure that many people will still be more attracted by the shiny ads for beta alanine containing supplements, there is little doubt that baking soda is the cheaper and at least acutely more effective buffering supplement.

That being said, the elevated PGC1-a levels in the study at hand add to the existing evidence that bicarb is more than a pre-/intra-workout acid buffer. And while it's still not 100% clear if it is a result of an increased use of intra-muscular glycogen or a consequnce of a reduced acid level during exercise, the increase in PGC1-a of which SuppVersity readers know that it has "IGF-1 Promoting, Myostatin Reducing, Muscle Building Effects" (learn more) make chronic sodium bicarbonate supplementation regimen even more interesting than they've been before | Comment on FB!

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The information provided on this website is for informational purposes only. It is by no means intended as professional medical advice. Do not use any of the agents or freely available dietary supplements mentioned on this website without further consultation with your medical practitioner.